US20250229713A1
SELF-STABILIZED EMERGENCY MARKER
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
Torc Robotics, Inc.
Inventors
Joseph R. Fox-Rabinovitz
Abstract
A vehicle marker locatable along a road or other surface travelled by an autonomous vehicle is disclosed. The marker comprises a marker body; a counterweight connected to the body. The marker body and counterweight are movable as a single self-stabilizing system. An axle supports the self-stabilizing system. The axle is rotatable relative to the self-stabilizing system and the self-stabilizing system has a center of mass that is located below the axle. The marker also comprises a number of supports, where each of the number of supports is rigidly fixed to the axle, and is rotatable with the axle relative to the self-stabilizing system, and wherein the location of the center of mass of the self-stabilizing system and rotatable axle and supports enable the marker to be self-righting when the marker is located along the surface.
Figures
Description
TECHNICAL FIELD
[0001]The field of the disclosure relates generally to emergency marker deployment in a vehicle, and more specifically, to an automated emergency marker deployment system and method for a vehicle.
BACKGROUND
[0002]An Autonomous Driving System (ADS) is any system that is partially or fully capable of driving a vehicle without the aid, assistance, or intervention of a human driver. In 2014, Society of Automotive Engineers (SAE) International created the SAE Levels of Driving Automation as a classification system for autonomous vehicles with the goal of providing greater clarity and transparency on the subject of autonomous technology. SAE's classification system consists of five levels of autonomy. At Level 0 Autonomy, the vehicle is incapable of autonomous driving and is controlled solely by a human driver. Level 1 Autonomy is characterized as one aspect of the driving process being taken over in isolation, using data from sensors and cameras, but the driver retains control of the vehicle. At Level 2 Autonomy, computers take on many of the driver's responsibilities, such as steering, however, a driver always must be present in the vehicle to take control in the event of an emergency and must keep a continual eye on the system. At Level 3 Autonomy, all aspects of driving are handled by the ADS, but the driver must be present at all times in case an intervention request is made. At Level 4 Autonomy, the ADS is capable of driving fully autonomously in proper settings without the assistance or intervention of a human driver. However, if a driver takes control of the vehicle, the ADS will disengage. At Level 5 Autonomy, the ADS is able to drive in known environments that can be navigated by a human driver. At Level 5, the ADS must be capable of managing all scenarios on its own and executing the entire dynamic driving task.
[0003]Autonomous vehicles employ four fundamental technologies: perception, localization, behaviors and planning, and control. Perception technologies enable an autonomous vehicle to sense and process its environment. Perception technologies process a sensed environment to identify and classify objects, or groups of objects, in the environment, for example, pedestrians, vehicles, or debris. Localization technologies determine, based on the sensed environment, for example, where in the world, or on a map, the autonomous vehicle is. Localization technologies process features in the sensed environment to correlate, or register, those features to known features on a map. Behaviors and planning technologies determine how to move through the sensed environment to reach a planned destination. Behaviors and planning technologies process data representing the sensed environment and localization or mapping data to plan maneuvers and routes to reach the planned destination for execution by a controller or a control module. Controller technologies use control theory to determine how to translate desired behaviors and trajectories into actions undertaken by the vehicle through its dynamic mechanical components. This includes steering, braking and acceleration. Information collected using perception and localization technologies may be used not only for safe driving of the autonomous vehicle. Accordingly, there is a need of applications in which the information collected using perception and localization technologies may be used.
[0004]Information collected using perception and localization technologies may be used in an autonomous vehicle after the vehicle completes an emergency stop and thereby achieve increased vehicle courtesy to other drives and limit risk. When a vehicle makes an emergency stop such as by exiting the road, pulling off on the side of the road or braking in the lane, driving regulations and laws require the vehicle driver to place markers near the stopped vehicle. The markers serve to alert approaching vehicles of the presence of the stopped vehicle. Drivers are typically required to use three markers to identify the stopped vehicle. When a non-autonomous or semi-autonomous vehicle, such as a tractor trailer driven by a human driver, makes an emergency stop, the driver exits the vehicle and manually places the emergency markers, such as triangles, near the vehicle and trailer in the required locations. For example, when a vehicle is stopped on a two-lane road with traffic in both directions, the driver locates one marker 100 feet in front of the vehicle, a second marker 10 feet behind the vehicle and a third marker 100 feet behind the vehicle.
[0005]In a fully autonomous vehicle there is no human driver. As a result, when the autonomous vehicle makes an emergency stop and the use of vehicle markers is required, there is no human driver in the autonomous vehicle to locate the markers relative to the vehicle. Accordingly, there is a need for a system for deploying markers in an autonomous vehicle when the autonomous vehicle executes an emergency stop.
[0006]This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the present disclosure described or claimed below. This description is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light and not as admissions of prior art.
SUMMARY
[0007]In one aspect, a vehicle marker locatable along a road or other surface travelled by an autonomous vehicle, comprises: a marker body; a counterweight connected to the marker body the marker body and counterweight movable as a single self-stabilizing system; an axle supporting the self-stabilizing system, the axle being rotatable relative to the self-stabilizing system, the self-stabilizing system having a center of mass that is located below the axle; and a number of supports, each of the number of supports being rigidly fixed to the axle, and the supports and axle being rotatable relative to the self-stabilizing system and wherein the location of the center of mass of the self-stabilizing system and rotatable axle and supports enable the marker to be self-righting when the marker is located along the surface.
[0008]Various refinements exist of the features noted in relation to the above-mentioned aspects. Further features may also be incorporated in the above-mentioned aspects as well. These refinements and additional features may exist individually or in any combination. For instance, various features discussed below in relation to any of the illustrated examples may be incorporated into any of the above-described aspects, alone or in any combination.
BRIEF DESCRIPTION OF DRAWINGS
[0009]The following drawings form part of the present specification and are included to further demonstrate certain aspects of the present disclosure. The disclosure may be better understood by reference to one or more of these drawings in combination with the detailed description of specific embodiments presented herein.
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[0026]Corresponding reference characters indicate corresponding parts throughout the several views of the drawings. Although specific features of various examples may be shown in some drawings and not in others, this is for convenience only. Any feature of any drawing may be reference or claimed in combination with any feature of any other drawing.
DETAILED DESCRIPTION
[0027]An example technical effect of the methods, systems, and apparatus described herein includes at least one of: (a) a marker deployment system for autonomous vehicles; (b) a marker deployment system for an autonomous vehicles that places markers in the required marker locations based on the vehicle location immediately after a specific emergency stop maneuver has been completed; (c) a marker deployment system that uses any of a mechanical arm, remote controlled vehicular or aerial drone to place the markers; (d) self-stabilizing markers per se, and (e) a marker deployment system that utilizes self-righting markers.
[0028]The following detailed description and examples set forth preferred materials, and procedures used in accordance with the present disclosure. This description and these examples, however, are provided by way of illustration only, and nothing therein shall be deemed to be a limitation upon the overall scope of the present disclosure. The following terms are used in the present disclosure as defined below.
[0029]An autonomous vehicle: An autonomous vehicle is a vehicle that is able to operate itself to perform various operations such as controlling or regulating acceleration, braking, steering wheel positioning, without any human intervention. An autonomous vehicle has an autonomy level of level-4 or level-5 recognized by National Highway Traffic Safety Administration (NHTSA).
[0030]A semi-autonomous vehicle: A semi-autonomous vehicle is a vehicle that is able to perform a number of driving related operations such as keeping the vehicle in lane and/or parking the vehicle without human intervention. A semi-autonomous vehicle has an autonomy level of level-1, level-2, or level-3 recognized by NHTSA.
[0031]A non-autonomous vehicle: A non-autonomous vehicle is a vehicle that is neither an autonomous vehicle nor a semi-autonomous vehicle. A non-autonomous vehicle has an autonomy level of level-0 recognized by NHTSA.
[0032]Mission control: Mission control, also referenced herein as a centralized or regionalized control, is a hub in communication with one or more autonomous vehicles of a fleet. Human agents, or artificial intelligence-based agents, positioned at mission control may monitor data or service requests received from the autonomous vehicle and may dispatch a rescue vehicle (also referenced herein as a service vehicle) at the autonomous vehicle's location.
[0033]An emergency stop occurs when a vehicle maneuver is executed that is intended to minimize potential risk to the vehicle and/or to other vehicles on the road. Such an emergency stop may include, but is not limited to exiting the road, pulling off on the side of the road or braking in the lane. As described in the present disclosure, a semi-autonomous vehicle, or a non-autonomous vehicle, such as a semi-autonomous truck or a non-autonomous truck, needs a human driver to operate the vehicle.
[0034]
[0035]As will be further disclosed herein through the preferred embodiments of the present disclosure, the marker deployment system 104 is used to locate markers in the desired locations relative to the vehicle 100. Drivers are required to place markers must be located around the vehicle 100 to warn other drivers approaching the vehicle 100 that the vehicle is unexpectedly stopped ahead. The markers are located in the required locations relative to the vehicle 100 in response to a completed emergency stop, and a determination of the location of the vehicle based on sensor data. Additionally, the markers must be in place around the vehicle soon after the emergency stop has been completed. For example, markers may need to be located around the vehicle within ten minutes after the emergency stop.
[0036]
[0037]The autonomy system 102 may use signals received from the one or more sensors 110 of the drive system 304. Additionally, the autonomy system 102 may use signals received from a server 310. The server 310 may be in communication with a computing device 312, such as, but not limited to, a user computing device (such as for manual remote control of the marker deployment system 104) and/or another vehicle in communication with the vehicle 100 to send and/or receive signals between vehicles. In some embodiments, the computing device may be a mission control computing system 324 that transmits control commands or data to the autonomous vehicle 100, such as navigation commands, and travel trajectories to the autonomous vehicle 100, and may also communicate commands for controlling the operation of the marker deployment system 104.
[0038]Additionally, or alternatively, mission control-based computing device 312 may receive processed or unprocessed sensor data from the autonomous vehicle 100, when the autonomous vehicle 100 determines, based upon analysis of the sensor data, that an emergency stop has been completed. The sensor data collected and sent to the computing device 312 by the autonomy system 102 may include data relating to the position and location of the autonomous vehicle 100 at the completion of the emergency stop. For example, the data may indicate that the trailer 105 of the vehicle 100 is at least partially located: a) in two lane traffic, 400 in
[0039]The autonomy system 102 may control the deployment of markers 600 of the marker deployment system 104. For example, the deployment of markers such as emergency markers may be based on the occurrence of an emergency stop by the vehicle 100. The emergency stop enables the vehicle 100 to reach a state that reduces the danger for the vehicle and other road users. An emergency stop can be performed abruptly or after pulling off the road, moving the vehicle to the shoulder of the road, or stopping the vehicle in the lane. The one or more sensors 110 may detect the vehicle has stopped at a location that does not comprise an aspect of the vehicle travel plan that may be stored in the memory 306 of the processing system 302. The processor 308 may compare the detected behavior of the vehicle to planned travel routes, location of the vehicle, expected speeds or other performance data, with threshold values, data, etc. stored in the memory 306 to identify if an emergency stop has been completed. If it is determined that an emergency stop has been completed markers 600 will be deployed by automatic deployment system 104. The determination of whether or not to deploy the markers 600 is made by the controller shortly after the processor determines for example, within ten minutes of the vehicle exhibiting behavior.
[0040]An embodiment of the marker deployment system 104 is shown in
[0041]A displacement control member/device (not shown) may be provided at the open end 123 of each telescoping tube 122 to impede the displacement of the moving, downstream tube 122 tube relative to the upstream tube and thereby prevent the moving telescoping tube from undesirably separating from the upstream tube. For example, using the telescoping tube reference numbers included in
[0042]Each downstream tube nests within the tube that is immediately upstream from the associated downstream tube, for example, tube 122-2 nests within tube 122-1, tube 122-3 nests within tube 122-2, etc. When the each of the tubes is nested in an adjacent upstream tube, the arm 120 is in a stowed or retracted orientation, as shown in
[0043]The upstream end of tube 122-1 is fixed to a prime mover 124. Generally, the prime mover serves to rotate the arm 120 about rotation axis 240. A hydraulic or pneumatic system (not shown) or other similar system using pressurized fluid to enable displacement of the tubes, may be used to enable the extension and retraction of the tubes 122-1 . . . 122-n. The hydraulic or pneumatic system may include a number of valves that are opened and closed as required to produce the desired extension or retraction of the system 104. During operation, signals may be sent to hydraulic system valves, to selectively open and close the valves as required to produce the flow and pressurization of the fluid to extend and retract the tubes. The tubes are retracted and extended along displacement axis 242. The arm may be rotated about the axis at any required magnitude angle. Axes 240 and 242 are shown in
[0044]As shown in
[0045]As shown in
[0046]As shown in
[0047]It should be understood that as the description proceeds, the configuration of arm 120 shown in
[0048]Specifically, the tube 122-1 is connected to the prime mover 124 at a prime mover hub 126 and the hub 126 is in turn connected to a motor 130. The motor may be any suitable motor including a vibration motor or a battery powered motor. For purposes of specifically describing an exemplary embodiment of the disclosure, a battery powered motor will be generally described. The battery of the motor 130 may be recharged by the power that is supplied to the truck 100 by the drive system 304. The motor is energized and receives a from the processing system 302 to cause the hub to rotate in the desired direction, clockwise or counterclockwise about axis of rotation 240. When the arm 120 is in the retracted/stowed orientation the length of the retracted arm may be between 6 feet and 8 feet, and preferably comprises a length that is less than the distance separating the wheels along opposite sides of the vehicle 100. By limiting the stowed length of the arm to the distance separating opposed wheels 112, the arm will be able to rotate below chassis 107 without contacting wheels 112 and enable the arm to be oriented to as required to effectively locate markers in the front and rear locations relative to the vehicle 100. If based on the dimensions of the vehicle 100 it is not possible to limit the stowed length of the arm to enable the arm to be rotated between front and rear directed orientations, a configuration as shown in
[0049]Provided along chassis 107 is marker support frame 500. The support frame may be a separate structure formed with the chassis or formed in the chassis. The marker support frame includes a base 502 and upper and side walls 504 made integral with the base 502 The walls and base define a chamber 506. The chamber may be open at both ends to enable the arm 120 to approach the chamber from the upstream or downstream end of the support base 500 to remove the markers 600 from the chamber 506. The chamber 506 is adapted to house a number of markers 600. See
[0050]As will be further described below, markers 600 include a counterweight 602 and supports 604, that are connected to the ends of rotatable axle 606. The axle is seated in a groove formed in the top of the counterweight 602 and is rotatable in the groove. The supports 604 rotate with the axle. When located in the chamber 506, the supports 604 are located on the floor 502 to support the markers in the chamber 506. Alternatively, the markers may be hung on a rod near the top of chamber 506.
[0051]Marker 600 is shown in
[0052]The center of mass CM of marker 600 is located below the axle 606. Locating the CM below the axle enables self-righting and self-stabilization of the body 608. The marker 600 shown in
[0053]Supports 604 have three legs 605 that are spaced apart by each adjacent leg by an angle 611. The supports have a substantially flat outer face. The supports are rigidly connected to the axle to be rotatable with the axle. Because of the angle A defined between the supports 604 and rotatable rod or axel 606, in combination with the location of the CM, regardless of how the marker lands on the road, gravity acting on the CM of the marker produces a stabilizing torque that moves the marker to the upright orientation shown in
[0054]In the present embodiment of the marker 600, the legs are spaced apart by equal angles of 120 degrees. Each leg has a base portion 607 proximate the axle. The base portion has a length “w” shown in
[0055]Operation of automatic marker deployment system 104 will be described.
[0056]Method 1200 for deploying markers 600 is presented in
[0057]In 1208 the marker deployment system is utilized to deploy the markers 600 on the associated road 401, 403, 405. The system 104 is powered using autonomy system 102. A signal is sent by the processing system 302 to activate the system 104. The processing system 302 may send a signal to any motors/other devices associated with the door or doors 508 to open the door and enable the arm to access the markers in the chamber 506. The arm 120 is extended and one or more markers 600 are collected from the chamber 506 by the arm at the end of tube 122-n. Using the deployment location data, the arm is selectively extended along the axis 242 as previously described to the length required to locate marker 600a along road 401. The arm 120a is shown in dashed font extended a length that enables marker 600a to be placed at location placement at d1, which may be 100 ft behind the vehicle. If required, the arm 120 may be telescopically retracted to obtain a second marker 600b from the chamber 506. If a second marker is connected to tube 122-n and obtaining a second marker 600b is not required, system 104 simply decreases the length of the arm 120, from length 120c to an arm length 120b, and locates the marker 600b at position d2 which may be 10 ft behind the vehicle. If the arm retrieved a marker from the chamber 506, the arm is extended to a length 120b where the marker is deployed. The arm 120b then retracts to the retracted orientation shown in
[0058]In a divided highway 403, three markers 600a, 600b and 600c may be initially removed from the chamber or single markers may be removed each time a marker is to be deployed. The arm is initially extended a length 120a, and marker 600a is located at position d1 which may be 200 ft behind the vehicle 100. If other markers are supported by tube 122-n, the arm 120 is shortened from length 120a to length 120b, and marker 600b is located at position d2 which may be 100 ft behind the vehicle 100. The arm length is further shortened from length 120b to 120c and marker 600c is located at position d3 a distance of 10 feet from the vehicle 100. If markers are retrieved singly, after the marker 600a is deployed, the arm 120a is fully retracted and marker 600b is retrieved from the chamber. The arm is extended to length 120b and marker 600b is located at position d2. The arm 120b is then fully retracted, and marker 600c is removed from chamber 506. The arm is extended to length 120c and marker 600c is located at position d3. Using self-righting markers 600, shown in
[0059]If the deployment system utilizes an arm 120 as shown in
[0060]
[0061]Turning to
[0062]The system 904 uses placement device 920 to deliver markers 600 to the defined locations along the road when the vehicle completes an emergency stop. The placement device is a drone and more specifically a remote-controlled vehicle such as a remote-controlled car. Between uses, the remote-controlled vehicle may be recharged using charging pad 914 that is provided on support base 910. When coupled on the charging pad 914, the vehicle is recharged using the batteries associated with the drive system for vehicle 100.
[0063]In use, a marker is loaded on or by vehicle 920 and a command signal is sent to the vehicle from the autonomy system 102 or mission control 324. The vehicle is controlled to move from chamber 908 and down ramp 912 in direction 930. The vehicle 920 may be controlled to the defined location for marker placement. Once at the desired location, the vehicle drops the marker in the required location. The self-orienting marker 600 assumes a vertical orientation when it is dropped by or otherwise unloaded from vehicle 920. The vehicle then returns to the chamber to obtain another marker. In an alternate embodiment of the disclosure shown in
[0064]
[0065]The method 1200 is applied when the placement devices 920 and 1020 are used to deploy the markers. A flying drone 1020 is shown in
[0066]The placement devices 920, 1020 may transport a single marker 600 from the chamber 908 to the defined location and after the marker is deployed may then return to the chamber to collect another marker to be located near the vehicle. Alternatively, a plurality of markers may be transported by the placement devices 920, 1020. After receiving a signal from the controller 302 that an emergency stop has occurred, the drone 920, 1020 is powered and loaded with one or a plurality of markers. The ramp 912 is also lowered by the controller. A signal is communicated to the motors/other devices that reposition the ramp. As shown in emergency stop schematics shown in
[0067]In all marker deployment methods described, after the drone returns to the chamber, the ramp is raised, and the drone is recharged by batteries of drive system 304.
[0068]As used herein, an element or step recited in the singular and proceeded with the word “a” or “an” should be understood as not excluding plural elements or steps unless such exclusion is explicitly recited. Furthermore, references to “one embodiment” of the disclosure or an “exemplary embodiment” are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features. Likewise, limitations associated with “one embodiment” or “an embodiment” should not be interpreted as limiting to all embodiments unless explicitly recited.
[0069]Disjunctive language such as the phrase “at least one of X, Y, or Z,” unless specifically stated otherwise, is generally intended, within the context presented, to disclose that an item, term, etc. may be either X, Y, or Z, or any combination thereof (e.g., X, Y, and/or Z). Likewise, conjunctive language such as the phrase “at least one of X, Y, and Z,” unless specifically stated otherwise, is generally intended, within the context presented, to disclose at least one of X, at least one of Y, and at least one of Z.
[0070]The disclosed systems and methods are not limited to the specific embodiments described herein. Rather, components of the systems or steps of the methods may be utilized independently and separately from other described components or steps.
[0071]This written description uses examples to disclose various embodiments, which include the best mode, to enable any person skilled in the art to practice those embodiments, including making and using any devices or systems and performing any incorporated methods. The patentable scope is defined by the claims and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences form the literal language of the claims.
Claims
What is claimed:
1. A vehicle marker locatable along a road or other surface travelled by an autonomous vehicle, the marker comprising:
a marker body;
a counterweight connected to the marker body the marker body and counterweight movable as a single self-stabilizing system;
an axle supporting the self-stabilizing system, the axle being rotatable relative to the self-stabilizing system, the self-stabilizing system having a center of mass that is located below the axle; and
a number of supports, each of the number of supports being rigidly fixed to the axle, and the supports and axle being rotatable relative to the self-stabilizing system and wherein the location of the center of mass of the self-stabilizing system and rotatable axle and supports enable the marker to be self-righting when the marker is located along the surface.
2. The marker of
3. The marker of
4. The marker of
5. The marker of
6. The marker as claimed in
7. The marker of
8. The marker of
9. The marker of
10. The marker as claimed in
11. The marker of
12. The marker of
13. The marker body of